Hierarchical Nanostructuring Array Enhances Mid-Hybridization for Accurate Herbal Identification via ITS2 DNA Barcode.

Abstract

It remains a technical challenge to accurately identify close species of herbal medicines, especially from adulterants, because of their highly identical phenotypes and chemical compositions. Here, we report a direct, sequencing-free, high-curvature nanostructuring-based electrochemical herb sensor (nanoE-herb sensor) to identify herbal species quickly and accurately using ITS2 barcodes. We engineer a nano-roughened carbon-supported gold nanostructuring array by photolithograph-free, one-step electrodeposition. The 3D fractal nanostructures exhibit a high deflection angle that largely enhances DNA hybridization efficiency, particularly for the midcomplementary hybridization, as compared to the 2D planar surface. More importantly, such a trans-scale array biointerface (including macroscale carbon and nanoscale gold branches) can overcome the detection barrier of slow diffusion of a long genomic sequence and inaccessibility of the sequestered variations in ITS2 secondary structures through the out-protruded 3D functional nanostructures. Our nanoE-herb sensor achieves a detection limit of 0.18 fM for the 64-mer fragment of saffron ITS2 barcode with midhybridization and shows superior specificity against even single-base mismatch. The sensor also precisely differentiates saffron from six other adulterants by directly detecting unpurified asymmetric PCR amplicons (∼500 bp) with ITS2 sequences, suggesting its great potential in the field identification of herbal medicinal species and pathogenic bacteria with specific DNA barcodes.